English

Macroscopic quantum spin tunnelling with two interacting spins

Strongly Correlated Electrons 2014-01-15 v2 High Energy Physics - Theory Quantum Physics

Abstract

We study the simple Hamiltonian, H=K(S1z2+S2z2)+λS1S2H=-K(S_{1z}^2 +S_{2z}^2)+ \lambda\vec S_1\cdot\vec S_2, of two, large, coupled spins which are taken equal, each of total spin ss with λ\lambda the exchange coupling constant. The exact ground state of this simple Hamiltonian is not known for an antiferromagnetic coupling corresponding to the λ>0\lambda>0. In the absence of the exchange interaction, the ground state is four fold degenerate, corresponding to the states where the individual spins are in their highest weight or lowest weight states, ,,,,,,,|\hskip-1 mm\uparrow, \uparrow\rangle, |\hskip-1 mm\downarrow, \downarrow\rangle, |\hskip-1 mm\uparrow, \downarrow\rangle, |\hskip-1 mm\downarrow, \uparrow\rangle, in obvious notation. The first two remain exact eigenstates of the full Hamiltonian. However, we show the that the two states ,,, |\hskip-1 mm\uparrow, \downarrow\rangle, |\hskip-1 mm\downarrow, \uparrow\rangle organize themselves into the combinations ±=12(,±)|\pm\rangle=\frac{1}{\sqrt 2} (|\hskip-1 mm\uparrow, \downarrow\rangle \pm |\hskip-1 mm\downarrow \uparrow\rangle), up to perturbative corrections. For the anti-ferromagnetic case, we show that the ground state is non-degenerate, and we find the interesting result that for integer spins the ground state is +|+\rangle, and the first excited state is the anti-symmetric combination |-\rangle while for half odd integer spin, these roles are exactly reversed. The energy splitting however, is proportional to λ2s\lambda^{2s}, as expected by perturbation theory to the 2sth2s^{\rm th} order. We obtain these results through the spin coherent state path integral.

Keywords

Cite

@article{arxiv.1304.3734,
  title  = {Macroscopic quantum spin tunnelling with two interacting spins},
  author = {Solomon A. Owerre and M. B. Paranjape},
  journal= {arXiv preprint arXiv:1304.3734},
  year   = {2014}
}

Comments

5 pages, no figures

R2 v1 2026-06-21T23:58:58.089Z